----------------------------------------------------------------------------- -- $Id: HsParseUtils.lhs,v 1.6 2003/10/20 17:19:23 sof Exp $ -- -- (c) The GHC Team 1997-2000 -- -- Utilities for the Haskell parser. -- ----------------------------------------------------------------------------- ToDo: Polish readInteger, readRational \begin{code} module HsParseUtils ( parseError -- String -> Pa , splitTyConApp -- HsType -> P (HsName,[HsType]) , mkRecConstrOrUpdate -- HsExp -> [HsFieldUpdate] -> P HsExp , checkPrec -- String -> P String , checkContext -- HsType -> P HsIPContext , checkIPContext -- HsIPContext -> P HsContext , checkAssertion -- HsType -> P HsAsst , checkInstHeader -- HsType -> P (HsContext, HsAsst) , checkClassHeader -- HsType -> P (HsContext, HsName, [HsType]) , checkDataHeader -- HsType -> P (HsContext,HsName,[HsName]) , checkPattern -- HsExp -> P HsPat , checkPatterns -- [HsExp] -> P [HsPat] , checkExpr -- HsExp -> P HsExp , checkValDef -- (SrcLoc, HsExp, HsRhs, [HsDecl]) -> P HsDecl , checkUnQual -- HsQName -> P HsName , readInteger -- String -> Integer , readRational -- String -> Rational , toVarHsName -- HsName -> HsName , toTyClsHsName -- HsName -> HsName ) where import HsSyn2 import HsParseMonad import Char(isDigit,isOctDigit,isHexDigit,digitToInt) import List(partition) import Ratio \end{code} \begin{code} parseError :: String -> P a parseError s = \r (SrcLoc y x f) -> failP (show f ++ ": " ++ show y ++ ":" ++ show x ++ ": " ++ s) r (SrcLoc y x f) splitTyConApp :: HsType -> P (HsName,[HsType]) splitTyConApp t0 = split t0 [] where split :: HsType -> [HsType] -> P (HsName,[HsType]) split (HsTyApp t u) ts = split t (u:ts) split (HsTyCon (UnQual t)) ts = returnP (t,ts) -- to cope with data [] = [] | a:[a] split (HsTyCon (Qual _ t)) ts = returnP (t,ts) split _ _ = parseError "Illegal data/newtype declaration" ----------------------------------------------------------------------------- -- Various Syntactic Checks checkContext :: HsType -> P HsIPContext checkContext (HsTyTuple True ts) = mapP checkCtxt ts where checkCtxt (HsTyIP n ty) = returnP (HsIP n ty) checkCtxt t0 = checkAssertion t0 `thenP` \ c -> returnP (HsAssump c) checkContext (HsTyIP n t) = returnP [HsIP n t] checkContext t = checkAssertion t `thenP` \c -> returnP [HsAssump c] checkIPContext :: HsIPContext -> P HsContext checkIPContext ls = case partition isIP ls of ([],cs) -> returnP (map (\ (HsAssump c) -> c) cs) (_,_) -> parseError "Unexpected implicit parameter in context" where isIP HsIP{} = True isIP _ = False -- Changed for multi-parameter type classes checkAssertion :: HsType -> P HsAsst checkAssertion = checkAssertion' [] where checkAssertion' ts (HsTyCon c) = returnP (c,ts) checkAssertion' ts (HsTyApp a t) = checkAssertion' (t:ts) a checkAssertion' _ _ = parseError "Illegal class assertion" checkInstHeader :: HsType -> P (HsContext, HsAsst) checkInstHeader (HsForAllType Nothing ctxt ty) = checkAssertion ty `thenP` \asst -> checkIPContext ctxt `thenP` \ctxt' -> returnP (ctxt', asst) checkInstHeader ty = checkAssertion ty `thenP` \asst -> returnP ([], asst) checkDataHeader :: HsType -> P (HsContext,HsName,[HsName]) checkDataHeader (HsForAllType Nothing cs t) = checkSimple "data/newtype" t [] `thenP` \(c,ts) -> checkIPContext cs `thenP` \cs' -> returnP (cs',c,ts) checkDataHeader ty = checkSimple "data/newtype" ty [] `thenP` \(c,ts) -> returnP ([],c,ts) checkClassHeader :: HsType -> P (HsContext,HsName,[HsName]) checkClassHeader (HsForAllType Nothing cs t) = checkSimple "class" t [] `thenP` \(c,ts) -> checkIPContext cs `thenP` \cs' -> returnP (cs',c,ts) checkClassHeader ty = checkSimple "class" ty [] `thenP` \(c,ts) -> returnP ([],c,ts) checkSimple :: String -> HsType -> [HsName] -> P ((HsName,[HsName])) checkSimple kw (HsTyApp l (HsTyVar a)) xs = checkSimple kw l (a:xs) checkSimple _kw (HsTyCon (UnQual t)) xs = returnP (t,xs) checkSimple _ (HsTyCon (Qual m t)) xs | m == prelude_mod = returnP (t,xs) -- for "special" declarations checkSimple kw _ _ = failP ("Illegal " ++ kw ++ " declaration") ----------------------------------------------------------------------------- -- Checking Patterns. -- We parse patterns as expressions and check for valid patterns below, -- converting the expression into a pattern at the same time. checkPattern :: HsExp -> P HsPat checkPattern e = checkPat e [] checkPatterns :: [HsExp] -> P [HsPat] checkPatterns es = mapP checkPattern es checkPat :: HsExp -> [HsPat] -> P HsPat checkPat (HsCon c) args = returnP (HsPApp c args) checkPat (HsApp f x0) args = checkPat x0 [] `thenP` \x -> checkPat f (x:args) checkPat e0 [] = case e0 of HsVar (UnQual x) -> returnP (HsPVar x) HsLit l -> returnP (HsPLit l) HsInfixApp l0 op r0 -> checkPat l0 [] `thenP` \l -> checkPat r0 [] `thenP` \r -> case op of HsCon c -> returnP (HsPInfixApp l c r) _ -> patFail HsTuple b es -> mapP (\e -> checkPat e []) es `thenP` \ps -> returnP (HsPTuple b ps) HsList es -> mapP (\e -> checkPat e []) es `thenP` \ps -> returnP (HsPList ps) HsParen e -> checkPat e [] `thenP` (returnP . HsPParen) HsAsPat n e -> checkPat e [] `thenP` (returnP . HsPAsPat n) HsWildCard -> returnP HsPWildCard HsIrrPat e -> checkPat e [] `thenP` (returnP . HsPIrrPat) HsRecConstr c fs0 -> mapP checkPatField fs0 `thenP` \fs -> returnP (HsPRec c fs) HsNegApp (HsLit l) -> returnP (HsPNeg (HsPLit l)) HsExpTypeSig _ e1 ty -> checkPat e1 [] `thenP` \e -> returnP (HsPTypeSig e ty) _ -> patFail checkPat _ _ = patFail checkPatField :: HsFieldUpdate -> P HsPatField checkPatField (HsFieldUpdate n e) = checkPat e [] `thenP` \p ->returnP (HsPFieldPat n p) patFail :: P a patFail = parseError "Parse error in pattern" ----------------------------------------------------------------------------- -- Check Expression Syntax checkExpr :: HsExp -> P HsExp checkExpr e0 = case e0 of HsVar _ -> returnP e0 HsIPVar _ -> returnP e0 HsCon _ -> returnP e0 HsLit _ -> returnP e0 HsInfixApp e1 e2 e3 -> check3Exprs e1 e2 e3 HsInfixApp HsApp e1 e2 -> check2Exprs e1 e2 HsApp HsNegApp e -> check1Expr e HsNegApp HsLambda ps e -> check1Expr e (HsLambda ps) HsLet bs e -> check1Expr e (HsLet bs) HsIf e1 e2 e3 -> check3Exprs e1 e2 e3 HsIf HsCase e1 alts0 -> mapP checkAlt alts0 `thenP` \alts -> checkExpr e1 `thenP` \e -> returnP (HsCase e alts) HsDo stmts -> mapP checkStmt stmts `thenP` (returnP . HsDo) HsTuple b es -> checkManyExprs es (HsTuple b) HsList es -> checkManyExprs es HsList HsParen e -> check1Expr e HsParen HsLeftSection e1 e2 -> check2Exprs e1 e2 HsLeftSection HsRightSection e1 e2 -> check2Exprs e1 e2 HsRightSection HsRecConstr c fields0 -> mapP checkField fields0 `thenP` \fields -> returnP (HsRecConstr c fields) HsRecUpdate e1 fields0 -> mapP checkField fields0 `thenP` \fields -> checkExpr e1 `thenP` \e -> returnP (HsRecUpdate e fields) HsEnumFrom e -> check1Expr e HsEnumFrom HsEnumFromTo e1 e2 -> check2Exprs e1 e2 HsEnumFromTo HsEnumFromThen e1 e2 -> check2Exprs e1 e2 HsEnumFromThen HsEnumFromThenTo e1 e2 e3 -> check3Exprs e1 e2 e3 HsEnumFromThenTo HsListComp e1 stmts0 -> mapP checkStmt stmts0 `thenP` \stmts -> checkExpr e1 `thenP` \e -> returnP (HsListComp e stmts) HsExpTypeSig loc e1 ty -> checkExpr e1 `thenP` \e -> returnP (HsExpTypeSig loc e ty) _ -> parseError "parse error in expression" -- type signature for polymorphic recursion!! check1Expr :: HsExp -> (HsExp -> a) -> P a check1Expr e f = checkExpr e `thenP` (returnP . f) check2Exprs :: HsExp -> HsExp -> (HsExp -> HsExp -> a) -> P a check2Exprs e1 e2 f = checkExpr e1 `thenP` \e1' -> checkExpr e2 `thenP` \e2' -> returnP (f e1' e2') check3Exprs :: HsExp -> HsExp -> HsExp -> (HsExp -> HsExp -> HsExp -> a) -> P a check3Exprs e1 e2 e3 f = checkExpr e1 `thenP` \e1' -> checkExpr e2 `thenP` \e2' -> checkExpr e3 `thenP` \e3' -> returnP (f e1' e2' e3') checkManyExprs :: [HsExp] -> ([HsExp] -> HsExp) -> P HsExp checkManyExprs es0 f = mapP checkExpr es0 `thenP` \es -> returnP (f es) checkAlt :: HsAlt -> P HsAlt checkAlt (HsAlt loc p galts0 bs) = checkGAlts galts0 `thenP` \galts -> returnP (HsAlt loc p galts bs) checkGAlts :: HsGuardedAlts -> P HsGuardedAlts checkGAlts (HsUnGuardedAlt e) = check1Expr e HsUnGuardedAlt checkGAlts (HsGuardedAlts galts) = mapP checkGAlt galts `thenP` (returnP . HsGuardedAlts) checkGAlt :: HsGuardedAlt -> P HsGuardedAlt checkGAlt (HsGuardedAlt loc stmts0 e0) = mapP checkStmt stmts0 `thenP` \stmts -> checkExpr e0 `thenP` \e -> returnP (HsGuardedAlt loc stmts e) checkStmt :: HsStmt -> P HsStmt checkStmt (HsGenerator p e) = check1Expr e (HsGenerator p) checkStmt (HsParStmt ss) = mapP checkStmt ss `thenP` \ ss1 -> returnP (HsParStmt ss1) checkStmt (HsQualifier e) = check1Expr e HsQualifier checkStmt s@(HsLetStmt _) = returnP s checkField :: HsFieldUpdate -> P HsFieldUpdate checkField (HsFieldUpdate n e) = check1Expr e (HsFieldUpdate n) ----------------------------------------------------------------------------- -- Check Equation Syntax checkValDef :: (SrcLoc, HsExp, HsRhs, [HsDecl]) -> P HsDecl checkValDef (srcloc, lhs0, rhs, whereBinds) = case isFunLhs lhs0 [] of Just (f,es) -> checkPatterns es `thenP` \ps -> returnP (HsFunBind [HsMatch srcloc f ps rhs whereBinds]) Nothing -> checkPattern lhs0 `thenP` \lhs -> returnP (HsPatBind srcloc lhs rhs whereBinds) -- A variable binding is parsed as an HsPatBind. isFunLhs :: HsExp -> [HsExp] -> Maybe (HsQName, [HsExp]) isFunLhs (HsInfixApp l (HsVar op) r) es = Just (op, l:r:es) isFunLhs (HsApp (HsVar f) e) es = Just (f,e:es) isFunLhs (HsApp (HsParen f) e) es = isFunLhs f (e:es) isFunLhs (HsApp f e) es = isFunLhs f (e:es) isFunLhs _ _ = Nothing ----------------------------------------------------------------------------- -- Check that an identifier or symbol is unqualified. -- For occasions when doing this in the grammar would cause conflicts. checkUnQual :: HsQName -> P HsName checkUnQual (Qual _ _) = parseError "Illegal qualified name" checkUnQual (UnQual n) = returnP n ----------------------------------------------------------------------------- -- Miscellaneous utilities toVarHsName :: HsName -> HsName toVarHsName (HsTyClsName n) = HsVarName n toVarHsName n = n toTyClsHsName :: HsName -> HsName toTyClsHsName (HsVarName n) = HsTyClsName n toTyClsHsName n = n checkPrec :: Integer -> P () checkPrec i | i >= 0 && i <= 9 = returnP () checkPrec i = parseError ("Illegal precedence: " ++ show i) -- Stolen from Hugs' Prelude readInteger :: String -> Integer readInteger ('0':'o':ds) = readInteger2 8 isOctDigit ds readInteger ('0':'x':ds) = readInteger2 16 isHexDigit ds readInteger ds = readInteger2 10 isDigit ds readInteger2 :: Integer -> (Char -> Bool) -> String -> Integer readInteger2 radix isDig ds | and $ map isDig ds = foldl1 (\n d -> n * radix + d) (map (fromIntegral . digitToInt) ds) | otherwise = error $ "readInteger2:expected all digits, got " ++ show ds -- Hack... readRational :: String -> Rational readRational xs = (readInteger (i++m))%1 * 10^^(case e of {[] -> 0; ('+':e2) -> read e2; _ -> read e} - length m) where (i,r1) = span isDigit xs (m,r2) = span isDigit (dropWhile (=='.') r1) e = dropWhile (=='e') r2 mkRecConstrOrUpdate :: HsExp -> [HsFieldUpdate] -> P HsExp mkRecConstrOrUpdate (HsCon c) fs = returnP (HsRecConstr c fs) mkRecConstrOrUpdate exp0 fs@(_:_) = returnP (HsRecUpdate exp0 fs) mkRecConstrOrUpdate _ _ = parseError "Empty record update" \end{code}